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用于高分辨率眼表摄影的结膜球结膜充血提取流程

Conjunctival Bulbar Redness Extraction Pipeline for High-Resolution Ocular Surface Photography.

作者信息

Ostheimer Philipp, Lins Arno, Helle Lars Albert, Romano Vito, Steger Bernhard, Augustin Marco, Baumgarten Daniel

机构信息

Institute of the Electrical and Biomedical Engineering, UMIT TIROL - Private University for Health Sciences and Health Technology, Hall in Tyrol, Austria.

Department of Research and Development, Occyo GmbH, Innsbruck, Austria.

出版信息

Transl Vis Sci Technol. 2025 Jan 2;14(1):6. doi: 10.1167/tvst.14.1.6.

DOI:10.1167/tvst.14.1.6
PMID:39786738
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11734545/
Abstract

PURPOSE

To extract conjunctival bulbar redness from standardized high-resolution ocular surface photographs of a novel imaging system by implementing an image analysis pipeline.

METHODS

Data from two trials (healthy; outgoing ophthalmic clinic) were collected, processed, and used to train a machine learning model for ocular surface segmentation. Various regions of interest were defined to globally and locally extract a redness biomarker based on color intensity. The image-based redness scores were correlated to clinical gradings (Efron) for validation.

RESULTS

The model to determine the regions of interest was verified for a segmentation performance, yielding mean intersections over union of 0.9639 (iris) and 0.9731 (ocular surface). All trial data were analyzed and a digital grading scale for the novel imaging system was established. Photographs and redness scores from visits weeks apart showed good feasibility and reproducibility. For scores within the same session, a mean coefficient of variation of 4.09% was observed. A moderate positive Spearman correlation (0.599) was found with clinical grading.

CONCLUSIONS

The proposed conjunctival bulbar redness extraction pipeline demonstrates that by using standardized imaging, a segmentation model and image-based redness scores' external eye photography can be classified and evaluated. Therefore, it shows the potential to provide eye care professionals with an objective tool to grade ocular redness and facilitate clinical decision-making in a high-throughput manner.

TRANSLATIONAL RELEVANCE

To empower clinicians and researchers with a high-throughput workflow by standardized imaging combined with an analysis tool based on artificial intelligence to objectively determine an image-based redness score.

摘要

目的

通过实施图像分析流程,从新型成像系统的标准化高分辨率眼表照片中提取结膜球结膜充血。

方法

收集、处理来自两项试验(健康人群;眼科门诊患者)的数据,并用于训练眼表分割的机器学习模型。定义了各个感兴趣区域,以基于颜色强度全局和局部提取充血生物标志物。将基于图像的充血评分与临床分级(Efron分级)进行相关性分析以进行验证。

结果

用于确定感兴趣区域的模型经分割性能验证,虹膜的平均交并比为0.9639,眼表的平均交并比为0.9731。对所有试验数据进行分析,并建立了新型成像系统的数字分级量表。相隔数周就诊时的照片和充血评分显示出良好的可行性和可重复性。对于同一次就诊内的评分,观察到平均变异系数为4.09%。与临床分级的Spearman相关性为中度正相关(0.599)。

结论

所提出的结膜球结膜充血提取流程表明,通过使用标准化成像,可对分割模型和基于图像的充血评分的眼外摄影进行分类和评估。因此,它显示出有潜力为眼科护理专业人员提供一种客观工具,以对眼部充血进行分级,并以高通量方式促进临床决策。

转化相关性

通过标准化成像结合基于人工智能的分析工具,为临床医生和研究人员提供高通量工作流程,以客观确定基于图像的确充血评分。

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